Sustainable Operations Management: An Enduring Stream or a Passing Fancy? Citation Drake, David, and Stefan Spinler. "Sustainable Operations Management: An Enduring Stream or a Passing Fancy?" Special Issue on the Environment. Manufacturing & Service Operations Management 15, no. 4 (Fall 2013). Published Version http://pubsonline.informs.org/doi/pdf/10.1287/msom.2013.0456 Permanent link http://nrs.harvard.edu/urn-3:HUL.InstRepos:28538425 Terms of Use This article was downloaded from Harvard University’s DASH repository, and is made available under the terms and conditions applicable to Open Access Policy Articles, as set forth at http:// nrs.harvard.edu/urn-3:HUL.InstRepos:dash.current.terms-of-use#OAP Share Your Story The Harvard community has made this article openly available. Please share how this access benefits you. Submit a story . Accessibility Sustainable Operations Management: An enduring stream or a passing fancy? David F. Drake HarvardBusinessSchool,HarvardUniversity,Boston,MA02163,U.S.A. [email protected] Stefan Spinler WHU–OttoBeisheimSchoolofManagement,56179Vallendar,Germany [email protected] Paul Kleindorfer was among the first to weigh in on and nurture the stream of Sustainable Operations Management.ThethoughtslaidoutherearebasedonconversationswehadwithPaulrelatingtothedrivers underlyingsustainabilityasamanagementissue:populationandpercapitaconsumptiongrowth,thelimited nature of resources and sinks, and the responsibility and exposure of firms to ensuing ecological risks and costs.Wethendiscusshowanoperationsmanagementlenscontributestotheissue,andcriteriatohelpthe Sustainable Operations Management perspective endure. This article relates to a presentation delivered by MorrisCohenfor Paul’sManufacturingandServiceOperationsManagementDistinguished Fellows Award, given at Columbia University, June 18, 2012. We wrote this article at Paul’s request. Key words: Sustainable operations management; Sustainability; Environment; Paul Kleindorfer History: Submitted March 29, 2013; revised June 22, 2013; revised June 29, 2013 Paul Kleindorfer was a pioneering and impactful force in the field of Sustainable Operations Management (Sustainable OM). He was among the first to lend his voice to the field (Kunreuther and Kleindorfer 1980), co-edit a number of the original special issues on the subject (Corbett and Kleindorfer 2001a, Corbett and Kleindorfer 2001b, and Corbett and Kleindorfer 2003), and co- author a survey of its early work (Kleindorfer et al. 2005). As two of Paul’s former students, we were among the many fortunate enough to benefit from his vast knowledge of the subject and his generosity in sharing it. The recent burgeoning of Sustainable OM was a point of pride for Paul. But, forever the mentor, he would not allow us to merely observe and contribute to its growth. He pushed us to question the stream’s ability to endure. It matters relatively little that the field is of interest today, he would say. When you look back over your career 20 years from now, will Sustainable OM prove to have been an enduring stream or a passing fancy? That question invariably led to two others: 1) Why is sustainability, broadly speaking, of growing interest?; and 2) What does the field of operations management (OM) have to contribute to it? 1 Drake and Spinler: SustainableOperationsManagement 2 Why is Sustainability of Growing Interest? The finite and semirenewable nature of many global resources and the limited ability of ecosystems to absorb pollutants have long been recognized1. However, because the renewable supply of these resources (e.g., water, forests, fish stocks) or the rate at which new sources were discovered (e.g., minerals,oil)vastlyexceededtheirconsumption,theirlimitednaturewasnothistoricallyperceived to be a binding constraint for the development of production systems to fuel economic growth. The future in which these natural assets might become limiting resources seemed distant, left largely to dystopian visions in film and literature. However, that future is now in sight. Two fundamental factors have thrown these constraints into relief: population growth and increasing per capita consumption. Thomas Malthus (1798) argued that population growth threatens economic sustainability, observing that population grew “in a geometrical ratio” (i.e., exponentially) while food produc- tion, in Malthus’ estimation, grew “in an arithmetical ratio” (i.e., linearly). While his theory has drawn criticism, Malthus receives credit for originating the discussion on economic sustainability and identifying population growth as one of its principal challenges. That growth has not abated. Worldwide population grew to 6.97 billion by 2011, an increase of 83% since 1970, with the vast majorityofthatgrowthoccurringinemergingeconomies(GlobalFinancialData2013).TheUnited Nations estimates that this growth will continue, albeit at a decreasing rate, reaching a global population of 9.31 billion by 2050 and over 10 billion by 2100 (UN, Department of Economic and Social Affairs, Population Division 2011). Similarly,since1970,acombinationofshorterproductlifecyclesandincreasedpurchasingpower hascontributedtoa138%increaseindevelopedeconomies’percapitaconsumptionwhileincreased earnings and greater access to consumer goods has helped drive a 231% increase in per capita consumption in emerging economies (World Bank 2013). Together, these trends propel exponential growth intheworld’saggregate consumption,withan astounding671% increasein consumption in emerging economies. Given that per capita consumption in these regions is still only about 1/17th that of the developed world (World Bank 2013), we should expect considerable growth ahead. Figures 1a-c below illustrate each of these trends. These underlying drivers—particularly population and income growth, and greater access to consumer goods in developing economies—do not seem likely to abate any time soon. With the continuanceofthesetrends,growthinglobalconsumptionalsoprojectsforward,placingincreasing demands on production systems worldwide. 1Asearlyas1272,forexample,smoginLondonwassobadthatKingEdwardIbannedtheburningofseacoal,with violations punishable by torture or death. The ban proved ineffective (Urbanito 1994). Drake and Spinler: SustainableOperationsManagement 3 8000 Population Aggregate Consumption 25000 7000 Developed economy population ons)6000 Emerging economy population ons) DDeevveellooppeedd Eeccoonnoommyy milli5000 billi EEmmeerrggiinngg Eeccoonnoommyy Population (234000000000 Yr2000 US$ (20000 1000 0 15000 1820 1850 1880 1910 1940 1970 2000 (a) Year Per Capita Consumption 20000 2000 Developing Economy (Yr2000 US$)11111246802468000000000000000000000000000 DEEDmmeevveeeerrllggooiipnnpegge ddEe ccEeooccnonoononmomommyyyy 24681111100000246800000000000000 Emerging Economy (Yr2000 US$) 105000000 0 0 0 1970 1980 1990 2000 2010 1970 1980 1990 2000 2010 (b) Year (c) Year Figure1 Trends in population (Figure 1a), per capita consumption (Figure 1b), and aggregate consumption (Figure 1c). Source: World Bank (2013). In their seminal work, The Limits to Growth, Meadows et al. (1972) refer to growth in consump- tion and the limited nature of “sources and sinks”—the finite supply of many natural resources and the finite capacity of ecosystems to absorb pollutants without conspicuous effects—as the core challenges to achieving an ecologically sustainable economy. This is not to say that all consump- tion of sources or emission of pollutants is unsustainable. Technological innovation can improve production efficiency with respect to source and sink use, mitigating certain sustainability con- cerns. Indeed, it is precisely such innovation that has spared us so far from the population crises predicted by Malthus. Advances in agrarian technology—the invention of iron plows in the 1790s, steel plows and threshing machines in the 1830s, modern irrigation and chemical fertilizers in the 1840s, and so forth—have enabled agricultural output to grow exponentially rather than at the linear rate predicted by Malthus. Even today, as illustrated in Figures 2a-c, agricultural factor efficiency(outputperunitoffactor input) intheUnitedStatescontinues toimproveexponentially, whether the factor considered is land, labor, or a multifactor combination of capital, materials, and labor. Agricultural output has thus managed to keep pace with population growth and hold Malthus’ sustainability crisis at bay. Drake and Spinler: SustainableOperationsManagement 4 Hectares per output (2005 basis)012341950Lan19d6 0Fa1c97t0or 19E80ffi1c99i0en2c0y00 Laborhours per output (2005 basis)1102468021950Lab1o96r0 F1a97c0tor19 80Eff19i9c0ie2n00c0y Total inputs per output (2005 basis)01231950Tot19a6l0 F1a97c0to1r9 80Eff19i9c0ie2n00c0y Figure2 Trends in the agricultural factor efficiency of land (Figure 2a), labor (Figure 2b), and all factors (Fig- ure 2c) relative to a 2005 basis. Source: USDA Economic Research Service (2013) This discussion relates closely to “IPAT” (Ehrlich and Holdren 1971), which stands for Impact = Population x Affluence x Technology, although in the discussion above we substitute per capita consumption for affluence (which is generally measured by per capita GDP). We do so because consumption indicates more directly the demands placed on production systems. To understand when consumption growth can lead to sustainability concerns that require reg- ulatory action and when those concerns might better be addressed by free-market-induced tech- nological change, one must first consider what levels of activity are sustainable. El Serafy (1989) and Daly (1990) outlined three intuitive sustainability criteria in the form of upper bounds on consumption and pollution rates: (i) Consumption of a renewable source is sustainable if it is no greater than the regeneration rate of that source; (ii) consumption of a nonrenewable source is sustainable if the economy substitutes an alternate material or technology at a sufficient rate that the nonrenewable resource is fully replaced before its reserves are exhausted; and (iii) the emission of pollution (or waste) is sustainable if it occurs at a rate no greater than the rate at which its sink (the ecosystem into which it is injected) can naturally assimilate it plus the rate at which the pollutant is actively removed. Figure 3 summarizes these sustainability criteria. Figure3 El Serafy (1989) and Daly (1990) criteria for maximum sustainable consumption and pollution. rates While these criteria are relatively straightforward to comprehend, adhering to them on a global scale is far from easy. Chief among the challenges are: (i) Uncertainty and debate with respect to Drake and Spinler: SustainableOperationsManagement 5 the various rates which define the criteria; and (ii) the pursuit of local objectives that require the consumptionofsharedresources.Theformermakesinterventionmoredifficult(whetherthatinter- vention is regulation or a free-market “invisible hand”) while the latter contributes to a “tragedy of the commons” on firm and national levels (Hardin 1968, Aflaki 2013). There is growing evidence that, as a result of these challenges, we have already ventured into unsustainable territory on a number of fronts. Rockstr¨om et al. (2009) identify nine “planetary boundaries,” building the case that the long- term stability of the biosphere would be at risk should any of these boundaries be violated. The authors find that human activity has already resulted in the violation of three of the thresholds, suggestingthatweareoperatinginthe“redzone”withrespecttoanthropogenicimpact.Similarly, Wackernagel et al. (1999) develop a framework to map source and sink consumption to land- area requirements; that is, to an “ecological footprint.” They estimate that we would require 1.5 earths to sustain current levels of human activity (footprintnetwork.org 2013). These findings are ultimately driven by an unsustainable rate of consumption of specific sources and an unsustainable rate of emission into specific sinks. Finite supply of natural resources The “overconsumption” of nonrenewable resources is seldom a matter of actually exhausting those resources, but rather a matter of incurring ever-increasing marginal costs. For example, if only the known reserves of copper and silver are considered (i.e., stocks which have been identified and which can be exploited economically), then we have only an estimated 22- and 15-year supply left, respectively (Mining, & Sustainable Development Project 2002). If, on the other hand, one were to estimate the entire resource base of both minerals (including undiscovered and currently uneconomicsources),thenthehorizonsbecome736and731years,respectively(Mining,&Sustain- able Development Project 2002). Further discoveries will be made and new extraction technologies will be developed, so that the actual horizon for both minerals will fall somewhere between these extremes. However, the marginal extraction cost is very likely to increase as we harvest veins less conveniently located in the Earth’s crust. Crudeoilisperhapsthemostcommonlycitednonrenewableresourceinthiscontext.Kerr(2011) and Murray and King (2012) indicate that since 2005, oil production has been inelastic to demand while prices have increased by about 15% per year. From this, they infer that production capacity has a ceiling of about 75 million barrels per day. They go on to argue that neither conventional nor unconventional oil sources (i.e., tar sands) are likely to significantly increase production beyond current levels. While average crude oil prices are expected to be 90-130 $/bbl by 2020 (US Energy Information Administration 2012), price volatility is likely to increase significantly. Substituting Drake and Spinler: SustainableOperationsManagement 6 naturalgasforcrudeoilmayofferaremedy.Indeed,theIEA(2012)toutsagoldenageofgasfueled by unconventional gas sources such as shale-gas fracturing (fracking). Such substitution—in this case, natural gas for oil—satisfies the Daly criteria for sustainable consumption of finite resources, however it can exacerbate sustainability concerns on other dimensions, as discussed below. As Simon (1998) argued, when the supply of a finite resource becomes increasingly scarce, tra- ditional supply-and-demand economics lead to a greater market price for the good relative to available extraction technologies and substitutes. This, in turn, incentivizes more exploration and technological innovation to access previously unknown, unobtainable, or uneconomic sources of the good. If supply becomes scarce enough, then the relative price increase incentivizes a tran- sition to alternate resources; e.g., transitioning from oil to natural gas. Such transitions may be disruptive, potentially requiring significant infrastructure investment and/or unsettling established market balance. However, in such a manner, free-market mechanisms can ensure the sustainability of priced resources, either by increasing supply through discovery and extraction or decreasing demand through substitution. Even so, free-market mechanisms are not a universal sustainability panacea. In the case of crude oil, the extraction of new sources (e.g., tar sands) and the transition to alternative resources (e.g., natural gas) can have unintended sustainability effects. While extrac- tion from tar sands increases the world’s oil reserves, it is significantly more emissions-intensive than conventional oil extraction (Lattanzio 2013). Similarly, the spike in natural gas supply from frackinghelpsalleviatepeakoilconcernsandprovidesalower-emissions-intensityalternativetooil. However, lower natural gas prices could reduce the adoption of zero-emissions energy technologies (e.g.,wind,solar,hydro)andsuppressinvestmentinenergyefficiencyimprovements.AsMcKibben (2012) notes, there are 2,795 gigatons of carbon embedded in proven oil, gas, and coal reserves cur- rently owned by fossil fuel firms—nearly five times the carbon that it is estimated would result in a two-degree-Celsius increase in average global temperature (Meinshausen et al. 2009). Therefore, while the discovery of more oil, gas, or coal may alleviate peak oil concerns, it does so at the cost of exacerbating sustainability concerns on other fronts. Further, free-market mechanisms break down for resources that are not priced. With water con- sumption more than doubling over the last century (UN Water 2013), it is not difficult to imagine the demand for fresh water outstripping its regeneration rate. Already, half of the developing world’s hospital beds are filled by those suffering from water-related diseases (UN Development Programme 2006). Worldwide, such diseases cause nearly 20% of deaths among children under the age of five (WHO/UNICEF 2009). Given asymmetric access to wealth and the universal need for water, pricing water in such scenarios to bring it within the control of market mechanisms would likely fail to equitably address these water scarcity concerns. Drake and Spinler: SustainableOperationsManagement 7 Finite capacity for ecosystems to absorb pollutants As OM scholars, it is natural to think of the sustainability of pollutant emissions into sinks in queuing terms. If the average arrival rate of waste into an ecosystem exceeds the average rate at which that waste can be served by that ecosystem (i.e., removed from or assimilated by it), then waste will accumulate infinitely and that ecosystem is unstable; i.e., the level of emissions being injected into the system is unsustainable. Therefore, evaluating ecosystem stability with respect to waste emissions requires an understanding of a pollutant’s arrival rate into the system and the rates at which the pollutant can be removed from and assimilated by the system. TheUSEnvironmentalProtectionAgency(2011)currentlymonitors,throughtheToxicsRelease Inventory alone, the emission of over 500 pollutants from nearly 3,000 facilities around the country while Europe, under the European Union Emissions Trading Scheme (often referred to as the EU-ETS), monitors over 11,000 facilities for their greenhouse gas (GHG) emissions (European Commission 2013). This suggests that regulators possess the capability to monitor the arrival of a large number of emissions/pollutants to various ecosystems on a vast scale. The greater challenges generally are estimating the rate at which specific sinks can naturally render those emissions harmless(i.e.,assimilatethem)andlimitingthearrivalofemissionsintosinksoncethosemaximum sustainable rates are identified. Because the absorptive rate of a sink is not always clear, there is room for both scientific and political debate, which can stall action, as we see in the ongoing carbon emission and climate change debate. Further, in the absence of a market price for pollutant emissions, the market mechanisms described above are not able to keep supply (i.e., available sink capacity) and demand (i.e., emission of pollutants) within sustainable limits. Despite these challenges, there are several examples where regulatory action has successfully limitedemissionstoratesbelowmaximumsustainablelevels.ExamplesincludeBritain’s1956Clean Air Act, which reduced smog in London (Urbanito 1994); Amendment IV of the 1990 US Clean Air Act, which reduced acid rain resulting from SO (US Environmental Protection Agency 2010); 2 and the US ban of the presumed carcinogen DDT from pesticides (US Environmental Protection Agency 1972). However, many other unsustainable practices have arisen or remain unaddressed. Perhaps the most widely cited is the emission of CO and other GHG relative to the biosphere’s 2 ability to assimilate them. Rockstr¨om et al. (2009) point out that the earth was ice-free until the concentration of atmospheric CO decreased to 450 +/- 100 parts per million (ppm). To maintain 2 the earth’s current climate system, of which the polar ice caps are such a crucial component, they suggest a boundary of 350 ppm, which we have already exceeded. It is therefore not surprising that the UN Intergovernmental Panel on Climate Change (IPCC) has stated that “warming of the climate system is unequivocal” and that “most of the observed increase in global average Drake and Spinler: SustainableOperationsManagement 8 temperaturessincethemid-20thcenturyisverylikelyduetotheobservedincreaseinanthropogenic [greenhouse gas] concentrations” (IPCC 2007). There are numerous, more localized examples of unsustainable emission into sinks, such as the emissionofairparticulatesinBeijingreachingnearlythreetimesthe“emergency”thresholdforair quality (Associated Press 2013, January 13); similar air quality issues in Singapore, Malaysia and Indonesia (Wong 2013, June 20); waste and sewage discharge into China’s Yellow River rendering over one-third of the river unusable even for agricultural and industrial purposes and less than one-sixth sufficiently clean for domestic use (Branigan 2008, November 25); and the accumulation of plastic debris throughout the world’s oceans and seas (Derraik 2002). As global consumption increases and production systems ramp to satisfy this demand, we should expect such reports to become more frequent. Implications for business ResearchcommissionedbytheCentralIntelligenceAgencyandconductedbytheNationalResearch Council (2012) concluded that climate crises are likely to increase in frequency and magnitude over the coming decades, disrupting regional water supplies, food markets, public health systems, and the global supply chains of strategic commodities. These risks clearly create humanitarian, geopolitical, and operational concerns related to political and social instability and the reliable availability of food, water, and raw materials. Given the interconnectedness of global markets, the uncertainties that such climate crises present for industry are extreme. Specifically with respect to climate change, firms can face three types of risk (Hultman et al. 2010). First, firms that operate unsustainably bear regulatory, economic, and legal risks from policy makers and from NGOs that lobby firms directly. Emissions caused by deforestation provide one such example. The UN IPCC estimated in 2007 that deforestation and forest degradation contribute approximately 17% of annual global CO emissions. Sourcing practices for palm oil, an 2 essential ingredient of cooking oil, soaps, and cosmetics, are frequently blamed for deforestation and destruction of animal habitats. Under pressure from NGOs backed by the IPCC’s finding, Unilever accepted a moratorium on palm oil harvesting in South East Asia (Greenpeace 2009). Second,firmslaunchingorinvestinginnewsustainableproductsandservicesalsofaceregulatory risk. Policy fluctuations and uncertainty as regulators grapple with the issue of climate change can significantly alter the value of such investments. In Germany, the current debate about the design of feed-in tariffs—long-term guaranteed purchase agreements for electricity generated from renewable energy—is one example. This policy mechanism helped increase the share of renewables in Germany from 3% in 1990 to 20% in 2011, with yearly investments peaking in 2010 at 27.9 billion EUR (BMU 2012). However, the currently negotiated redesign with significantly lower Drake and Spinler: SustainableOperationsManagement 9 remuneration has led to the cancellation of planned investments in renewable energy. In general, as climate change policies are continually refined, the value of sustainability opportunities will be subject to substantial changes with the ebb and flow of policy. Third, firms’ profits and cash-flows in many sectors are directly exposed to climate instability. This set of firms is larger than one might think. Cachon et al. (2012), for example, estimate that US auto manufacturers lose an average of about 1.5% of their available capacity per year due to severe weather, results that the authors point out become more important given the threat of anthropogenic climate change. Aon estimates that there was $200 billion in climate-catastrophe- relateddamagein2012,including$65billionfromhurricaneSandyand$35billionfromadroughtin the USMidwest (Aon Benfield2013). Given the predictedincrease in thefrequency andmagnitude of climate crises (National Research Council 2012), we should expect these costs to grow under any business-as-usual scenario. To mitigate such costs, Kleindorfer (2009) challenges the insurance industry to become a knowledge broker in the area of climate risk, with the goal of integrating risk management solutions with sustainability strategies. Similarly, Jaffe et al. (2010) and Kleindorfer et al. (2012a) advocate multiyear property insurance as a mechanism by which individuals can reduce their financial exposure to climate change, replacing that volatility with stable insurance premiums over several years. How Can an Operations Management Lens Contribute? OM offers a vital sustainability perspective. At the micro-level, firms’ operational decisions deter- mine the production and distribution technologies and system design that they employ. These in turn determine how efficiently (and which) materials and energy are consumed as well as the type and intensity of waste injected into ecosystems, which aggregate to determine global source and sink consumption rates and, ultimately, the sustainability of an ecosystem with respect to human activity. Sustainable OM, therefore, potentially has an important role to play in contributing to solutions for the sustainability challenges that we currently face. However, to fulfill that potential, we must deliver on the stream’s implicit promise—to generate research that enables production and distribution systems to operate more efficiently with respect to their environmental and social impact. Research that fulfills this promise must not only be rigorously executed, it must also directlyorindirectlyinfluencefirmdecisionsand/orshapepolicy.Suchresearchwillsatisfyatleast one, and ideally both, of the following criteria: (i) it engages practitioners and/or policy makers; and (ii) it embraces the multidisciplinary nature of the sustainability challenge. Not satisfied with a handful of paragraphs at the end of his papers to make the case for his work’s managerial implications, Paul’s modus operandi throughout his career was to engage with firms and policy makers to fine tune research questions and communicate results. He embraced the
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